On the Analytical and Computational Methodologies for Modelling Two-wheeled Vehicles within the Multibody Dynamics Framework: A Systematic Literature Review

[1] Saccon, A., Hauser, J., An efficient Newton method for general motorcycle kinematics, Vehicle System Dynamics, 2009, 47(2), 221–241.
[2] Guo, N., Jiang, R., Wong, S., Hao, Q.Y., Xue, S.Q., Hu, M.B., Bicycle flow dynamics on wide roads: Experiments and simulation, Transportation research part C: emerging technologies, 2021, 125, 103012.
[3] Tanelli, M., Corno, M., Savaresi, S.M., eds., Modelling, Simulation and Control of Two-Wheeled Vehicles, John Wiley & Sons, Ltd, Chichester, UK, 2014.
[4] Huang, Y., Liang, W., Chen, Y., Stability regions of vehicle lateral dynamics: Estimation and analysis, Journal of Dynamic Systems, Measurement, and Control, 2021, 143(5).
[5] Prince, P., Al-Jumaily, A., Bicycle steering and roll responses, Proceedings of the Institution of Mechanical Engineers, Part K: Journal of Multi-body Dynamics, 2012, 226(2), 95–107.
[6] Fenre, M.D., Klein-Paste, A., Bicycle rolling resistance under winter conditions, Cold Regions Science and Technology, 2021, 187, 103282.
[7] Chen, C.K., Dao, T.K., Speed-adaptive roll-angle-tracking control of an unmanned bicycle using fuzzy logic, Vehicle System Dynamics, 2010, 48(1), 133–147.
[8] García-Agúndez, A., García-Vallejo, D., Freire, E., Linearization approaches for general multibody systems validated through stability analysis of a benchmark bicycle model, Nonlinear Dynamics, 2021, 103(1), 557–580.
[9] Chu, T.D., Chen, C.K., Modelling and model predictive control for a bicycle-rider system, Vehicle System Dynamics, 2018, 56(1), 128–149.
[10] Huang, L., An approach for bicycle’s kinematic analysis, Proceedings of the Institution of Mechanical Engineers, Part K: Journal of Multi-body Dynamics, 2017, 231(1), 278–284.
[11] Nehaoua, L., Arioui, H., Seguy, N., Mammar, S., Dynamic modelling of a two-wheeled vehicle: Jourdain formalism, Vehicle System Dynamics, 2013, 51(5), 648–670.
[12] Chen, J., Li, K., Li, K., Yu, P.S., Zeng, Z., Dynamic planning of bicycle stations in dockless public bicycle-sharing system using gated graph neural network, ACM Transactions on Intelligent Systems and Technology (TIST), 2021, 12(2), 1–22.
[13] Klug, S., Moia, A., Verhagen, A., Görges, D., Savaresi, S., The influence of bicycle fork bending on brake control, Vehicle System Dynamics, 2019, 3114, 1–21.
[14] Mao, G., Hou, T., Liu, X., Zuo, J., Kiyawa, A.H.I., Shi, P., Sandhu, S., How can bicycle-sharing have a sustainable future? a research based on life cycle assessment, Journal of Cleaner Production, 2021, 282, 125081.
[15] Damon, P.M., Ichalal, D., Arioui, H., Steering and Lateral Motorcycle Dynamics Estimation: Validation of Luenberger LPV Observer Approach, IEEE Transactions on Intelligent Vehicles, 2019, 4(2), 277–286.
[16] Wierbos, M.J., Knoop, V., Hänseler, F., Hoogendoorn, S., A macroscopic flow model for mixed bicycle–car traffic, Transportmetrica A: transport science, 2021, 17(3), 340–355.
[17] Slimi, H., Arioui, H., Nouveliere, L., Mammar, S., Motorcycle speed profile in cornering situation, Proceedings of the 2010 American Control Conference, IEEE, 1172–1177.
[18] Zouzias, D., De Bruyne, G., Ní Annaidh, A., Trotta, A., Ivens, J., The effect of the scalp on the effectiveness of bicycle helmets’ anti-rotational acceleration technologies, Traffic injury prevention, 2021, 22(1), 51–56.
[19] Kooijman, J., Schwab, A., A review on bicycle and motorcycle rider control with a perspective on handling qualities, Vehicle System Dynamics, 2013, 51(11), 1722–1764.
[20] Doria, A., Formentini, M., Tognazzo, M., Experimental and numerical analysis of rider motion in weave conditions, Vehicle System Dynamics, 2012, 50(8), 1247–1260.
[21] Popov, A.A., Rowell, S., Meijaard, J.P., A review on motorcycle and rider modelling for steering control, Vehicle System Dynamics, 2010, 48(6), 775–792.
[22] Griffin, J.W., Popov, A.A., Multibody dynamics simulation of an all-wheel-drive motorcycle for handling and energy efficiency investigations, Vehicle System Dynamics, 2018, 56(7), 983–1001.
[23] Schwab, A.L., Meijaard, J.P., A review on bicycle dynamics and rider control, Vehicle System Dynamics, 2013, 51(7), 1059–1090.
[24] Lot, R., Fleming, J., Gyroscopic stabilisers for powered two-wheeled vehicles, Vehicle System Dynamics, 2019, 57(9), 1381–1406.
[25] Limebeer, D.J.N., Sharp, R.S., Evangelou, S., The stability of motorcycles under acceleration and braking, Proceedings of the Institution of Mechanical Engineers, Part C: Journal of Mechanical Engineering Science, 2001, 215(9), 1095–1109.
[26] Cossalter, V., Lot, R., Maggio, F., The Modal Analysis of a Motorcycle in Straight Running and on a Curve, Meccanica, 2004, 39(1), 1–16.
[27] Milani, S., Marzbani, H., Azad, N.L., Melek, W., Jazar, R.N., The importance of equation η= µn 2 in dimensional analysis and scaled vehicle experiments in vehicle dynamics, Vehicle System Dynamics, 2021, 1–30.
[28] Tomiati, N., Colombo, A., Magnani, G., A nonlinear model of bicycle shimmy, Vehicle System Dynamics, 2019, 57(3), 315–335.
[29] Manrique, C., Pappalardo, C.M., Guida, D., A model validating technique for the kinematic study of two-wheeled vehicles, Grabchenko’s International Conference on Advanced Manufacturing Processes, Springer, 549–558.
[30] Pappalardo, C.M., Lettieri, A., Guida, D., A general multibody approach for the linear and nonlinear stability analysis of bicycle systems. part i: Methods of constrained dynamics, Journal of Applied and Computational Mechanics, 2021, 7(2), 655–670.
[31] Pappalardo, C.M., Lettieri, A., Guida, D., A general multibody approach for the linear and nonlinear stability analysis of bicycle systems. part ii: Application to the whipple-carvallo bicycle model, Journal of Applied and Computational Mechanics, 2021, 7(2), 671–700.
[32] Genta, G., Motor Vehicle Dynamics: Modeling and Simulation, vol. 43 of Series on Advances in Mathematics for Applied Sciences, WORLD SCIENTIFIC, 1997.
[33] Astrom, K., R.E. Klein, A. Lennartsson, Klein, R., Lennartsson, A., Bicycle dynamics and control: adapted bicycles for education and research, IEEE Control Systems, 2005, 25(4), 26–47.
[34] Frosali, G., Ricci, F., Kinematics of a bicycle with toroidal wheels, Communications in Applied and Industrial Mathematics, 2012, 3(1), 24.
[35] Zhang, Y., Li, J., Yi, J., Song, D., Balance control and analysis of stationary riderless motorcycles, 2011 IEEE International Conference on Robotics and Automation, IEEE, 3018–3023.
[36] Cossalter, V., Lot, R., Massaro, M., An advanced multibody code for handling and stability analysis of motorcycles, Meccanica, 2011, 46(5), 943–958.
[37] Sharma, A., Stability analysis of bicycles and motorcycles : a control theoretic perspective, Ph.D. thesis, Imperial College London, London, United Kingdom, 2010.
[38] Herlihy, D.V., Bicycle: The History, Yale University Press, 2004.
[39] Cain, S.M., Perkins, N.C., Comparison of experimental data to a model for bicycle steady-state turning, Vehicle System Dynamics, 2012, 50(8), 1341–1364.
[40] Prince, J., An investigation into bicycle performance and design, Ph.D. thesis, Auckland University of Technology, Auckland, New Zealand, 2014.
[41] Zhang, S.p., Tak, T.o., A design sensitivity analysis of bicycle stability and experimental validation, Journal of Mechanical Science and Technology, 2020, 34(9), 3517–3524.
[42] Bonisoli, E., Lisitano, D., Dimauro, L., Peroni, L., A Proposal of Dynamic Behaviour Design Based on Mode Shape Tracing: Numerical Application to a Motorbike Frame, Conference Proceedings of the Society for Experimental Mechanics Series, vol. 4, 2020, 149–158.
[43] Paudel, M., Yap, F.F., Development of an improved design methodology and front steering design guideline for small-wheel bicycles for better stability and performance, Proceedings of the Institution of Mechanical Engineers, Part P: Journal of Sports Engineering and Technology, 2020, 234(3), 227–244.
[44] Sharma, A., Limebeer, D.J.N., Dynamic stability of an aerodynamically efficient motorcycle, Vehicle System Dynamics, 2012, 50(8), 1319–1340.
[45] Plöchl, M., Edelmann, J., Angrosch, B., Ott, C., On the wobble mode of a bicycle, Vehicle System Dynamics, 2012, 50(3), 415–429.
[46] Klinger, F., Nusime, J., Edelmann, J., Plöchl, M., Wobble of a racing bicycle with a rider hands on and hands off the handlebar, Vehicle System Dynamics, 2014, 52(sup1), 51–68.
[47] Kaul, S., Influence of a Vibration Isolation System on Planar Dynamics of a Motorcycle, The International Journal of Acoustics and Vibration, 2020, 25(1), 96–103.
[48] Cain, S.M., An experimental investigation of human/bicycle dynamics and rider skill in children and adults, Ph.D. thesis, University of Michigan, Michigan, 2013.
[49] Kooijman, J.D.G., Bicycle rider control: observations, modeling & experiments, Ph.D. thesis, Delft University of Technology, Delft, Netherlands, 2012.
[50] Jones, D.E.H., The stability of the bicycle, Physics Today, 1970, 23(4), 34–40.
[51] Sharp, R., Evangelou, S., Limebeer, D., Advances in the Modelling of Motorcycle Dynamics, Multibody System Dynamics, 2004, 12(3), 251–283.
[52] Singhania, S., Kageyama, I., Karanam, V.M., Study on Low-Speed Stability of a Motorcycle, Applied Sciences, 2019, 9(11), 2278.
[53] Singhania, S., Kageyama, I., Karanam, V.M., Steering control to balance a motorcycle at low speeds based on riders’ input, Proceedings of the Institution of Mechanical Engineers, Part D: Journal of Automobile Engineering, 2020, 234(12), 2892–2904.
[54] Salvati, L., d’Amore, M., Fiorentino, A., Pellegrino, A., Sena, P., Villecco, F., Development and testing of a methodology for the assessment of acceptability of lka systems, Machines, 2020, 8(3), 47.
[55] Salvati, L., d’Amore, M., Fiorentino, A., Pellegrino, A., Sena, P., Villecco, F., On-road detection of driver fatigue and drowsiness during mediumdistance journeys, Entropy, 2021, 23(2), 135.
[56] Sanjurjo, E., Naya, M.A., Cuadrado, J., Schwab, A.L., Roll angle estimator based on angular rate measurements for bicycles, Vehicle System Dynamics, 2019, 57(11), 1705–1719.
[57] Savino, G., Lot, R., Massaro, M., Rizzi, M., Symeonidis, I., Will, S., Brown, J., Active safety systems for powered two-wheelers: A systematic review, Traffic Injury Prevention, 2020, 21(1), 78–86.
[58] Lucci, C., Marra, M., Huertas-Leyva, P., Baldanzini, N., Savino, G., Investigating the feasibility of motorcycle autonomous emergency braking (MAEB): Design criteria for new experiments to field test automatic braking, MethodsX, 2021, 8(September 2020), 101225.
[59] Hima, S., Nehaoua, L., Seguy, N., Arioui, H., Motorcycle Dynamic Model Synthesis for Two Wheeled Driving Simulator, 2007 IEEE Intelligent Transportation Systems Conference, IEEE, 812–817.
[60] James, S.R., Lateral Dynamics of an Offroad Motorcycle by System Identification, Vehicle System Dynamics, 2002, 38(1), 1–22.
[61] Saccon, A., Hauser, J., Beghi, A., A Virtual Rider for Motorcycles: Maneuver Regulation of a Multi-Body Vehicle Model, IEEE Transactions on Control Systems Technology, 2013, 21(2), 332–346.
[62] Zhu, S., Murakami, S., Nishimura, H., Motion analysis of a motorcycle taking into account the rider’s effects, Vehicle System Dynamics, 2012, 50(8), 1225–1245.
[63] Haas, S., Dück, M., Winkler, A., Grabmair, G., Oberpeilsteiner, S., Free Multibody Cosimulation Based Prototyping of Motorcycle Rider Assistance Systems, SAE Technical Paper, SAE International, Minneapolis, Minnesota, 1–12.
[64] Limebeer, D.J.N., Sharp, R.S., Evangelou, S., Motorcycle Steering Oscillations due to Road Profiling, Journal of Applied Mechanics, 2002, 69(6), 724–739.
[65] Sharp, R.S., Limebeer, D.J., A Motorcycle Model for Stability and Control Analysis, Multibody System Dynamics, 2001, 6(2), 123–142.
[66] Sharp, R.S., Stability, Control and Steering Responses of Motorcycles, Vehicle System Dynamics, 2001, 35(4-5), 291–318.
[67] Zhang, Y., Yi, J., Dynamic modeling and balance control of human/bicycle systems, 2010 IEEE/ASME International Conference on Advanced Intelligent Mechatronics, IEEE, 1385–1390.
[68] Cossalter, V., Doria, A., Garbin, S., Lot, R., Frequency-domain method for evaluating the ride comfort of a motorcycle, Vehicle System Dynamics, 2006, 44(4), 339–355.
[69] Kaul, S., Dhingra, A.K., Engine mount optimisation for vibration isolation in motorcycles, Vehicle System Dynamics, 2009, 47(4), 419–436.
[70] Robledo-Ricardo, L.A., Nonlinear Stochastic Analysis of Motorcycle Dynamics, Ph.D. thesis, Rice University, Texas, USA, 2013.
[71] Kaul, S., Planar Dynamics of a Motorcycle: Influence of Vibration Isolation System Nonlinearity, The International Journal of Acoustics and Vibration, 2020, 25(4), 597–608.
[72] Huang, C.F., Tung, Y.C., Lu, H.T., Yeh, T.J., Balancing control of a bicycle-riding humanoid robot with center of gravity estimation, Advanced Robotics, 2018, 32(17), 918–929.
[73] Lake, K., Thomas, R., Williams, O., The influence of compliant chassis components on motorcycle dynamics: an historical overview and the potential future impact of carbon fibre, Vehicle System Dynamics, 2012, 50(7), 1043–1052.
[74] Mavroudakis, B., Eberhard, P., Analysis of alternative front suspension systems for motorcycles, Vehicle System Dynamics, 2006, 44(sup1), 679–689.
[75] Cossalter, V., Lot, R., A Motorcycle Multi-Body Model for Real Time Simulations Based on the Natural Coordinates Approach, Vehicle System Dynamics, 2002, 37(6), 423–447.
[76] Barbagallo, R., Sequenzia, G., Oliveri, S., Cammarata, A., Dynamics of a high-performance motorcycle by an advanced multibody/control cosimulation, Proceedings of the Institution of Mechanical Engineers, Part K: Journal of Multi-body Dynamics, 2016, 230(2), 207–221.
[77] Olds, T., Modelling Human Locomotion, Sports Medicine, 2001, 31(7), 497–509.
[78] Pappalardo, C.M., A natural absolute coordinate formulation for the kinematic and dynamic analysis of rigid multibody systems, Nonlinear Dynamics, 2015, 81(4), 1841–1869.
[79] Pappalardo, C.M., Guida, D., On the Lagrange multipliers of the intrinsic constraint equations of rigid multibody mechanical systems, Archive of Applied Mechanics, 2018, 88(3), 419–451.
[80] Pappalardo, C., Guida, D., On the Computational Methods for Solving the Differential-Algebraic Equations of Motion of Multibody Systems, Machines, 2018, 6(2), 20.
[81] Lot, R., Lio, M.D., A Symbolic Approach for Automatic Generation of the Equations of Motion of Multibody Systems, Multibody System Dynamics, 2004, 12(2), 147–172.
[82] Sayers, M.W., Vehicle Models for RTS Applications, Vehicle System Dynamics, 1999, 32(4-5), 421–438.
[83] Meijaard, J.P., Popov, A.A., Numerical Continuation of Solutions and Bifurcation Analysis in Multibody Systems Applied to Motorcycle Dynamics, Nonlinear Dynamics, 2006, 43(1-2), 97–116.
[84] Meijaard, J.P., Popov, A.A., Multi-body modelling and analysis into the non-linear behaviour of modern motorcycles, Proceedings of the Institution of Mechanical Engineers, Part K: Journal of Multi-body Dynamics, 2007, 221(1), 63–76.
[85] Sharp, R.S., On the Stability and Control of the Bicycle, Applied Mechanics Reviews, 2008, 61(6).
[86] Karanam, V.M., Chatterjee, A., Common underlying steering curves for motorcycles in steady turns, Vehicle System Dynamics, 2011, 49(6), 931–948.
[87] Sharp, R.S., Watanabe, Y., Chatter vibrations of high-performance motorcycles, Vehicle System Dynamics, 2013, 51(3), 393–404.
[88] Jonker, J.B., Meijaard, J.P., SPACAR — Computer Program for Dynamic Analysis of Flexible Spatial Mechanisms and Manipulators, Multibody Systems Handbook, Springer Berlin Heidelberg, Berlin, Heidelberg, 1990, 123–143.
[89] Meijaard, J., Papadopoulos, J.M., Ruina, A., Schwab, A., Linearized dynamics equations for the balance and steer of a bicycle: a benchmark and review, Proceedings of the Royal Society A: Mathematical, Physical and Engineering Sciences, 2007, 463(2084), 1955–1982.
[90] Bulsink, V.E., Doria, A., van de Belt, D., Koopman, B., The effect of tyre and rider properties on the stability of a bicycle, Advances in Mechanical Engineering, 2015, 7(12), 168781401562259.
[91] Bruni, S., Meijaard, J.P., Rill, G., Schwab, A.L., State-of-the-art and challenges of railway and road vehicle dynamics with multibody dynamics approaches, Multibody System Dynamics, 2020, 49(1), 1–32.
[92] Corno, M., Panzani, G., Savaresi, S.M., Single-Track Vehicle Dynamics Control: State of the Art and Perspective, IEEE/ASME Transactions on Mechatronics, 2015, 20(4), 1521–1532.
[93] Garziad, M., Review on Dynamics, Control and Stability of Two Wheeled Vehicle, International Journal of Mechanical Engineering, 2019, 6(7), 1–7.
[94] Rankine, W.J.M., On the dynamical principles of the motion of velocipedes, The Engineer, 1869, 28(79), 129.
[95] Whipple, F.J., The stability of the motion of a bicycle, Quarterly Journal of Pure and Applied Mathematics, 1899, 30(120), 312–321.
[96] Carvallo, E., Théorie du movement du monocycle, part 2: Théorie de la bicyclette, J. Ec. Polytech. Paris, 1901, 6, 1–118.
[97] Timoshenko, S., Young, D.H., Advanced dynamics, McGraw-Hill Book Co., New York, 1948.
[98] Döehring, E., Über die stabilität und die lenkkräfte von einspurfahrzeugen, Ph.D. thesis, Technische Universität Braunschweig, Braunschweig, Germany, 1953.
[99] Neimark, J.I., Fufaev, N.A., Dynamics of Nonholonomic Systems, Translations of Mathematical Monographs, 33, American Mathematical Society, 1972.
[100] Dikarev, E., Dikareva, S., Fufaev, N., Effect of inclination of steering axis and of stagger of the front wheel on stability of motion of a bicycle, Izv. Akad. Nauk SSSR Mekh. Tverd. Tela, 1981, 16, 69–73.
[101] Hand, R.S., Comparisons and stability analysis of linearized equations of motion for a basic bicycle model, Master’s thesis, Cornell University, Ithaca (NY), 1988.
[102] Sharp, R.S., The Stability and Control of Motorcycles, Journal of Mechanical Engineering Science, 1971, 13(5), 316–329.
[103] Roland, R.D., Lynch, J.P., Bicycle dynamics: Tire characteristics and rider modeling, Tech. rep., Cornell Aeronautical Laboratory, Buffalo (NY), 1972, (Technical Report YA-3063-K-2).
[104] Roland, R.D., Computer simulation of bicycle dynamics, Proceedings of the ASME Symposium Mechanics and Sport, 35–83.
[105] Sharp, R.S., The Influence of Frame Flexibility on the Lateral Stability of Motorcycles, Journal of Mechanical Engineering Science, 1974, 16(2), 117–120.
[106] Jennings, G., A Study of Motorcycle Suspension Damping Characteristics, National West Coast Meeting, SAE International, United States.
[107] Sharp, R.S., The Influence of the Suspension System on Motorcycle Weave-mode Oscillations, Vehicle System Dynamics, 1976, 5(3), 147–154.
[108] Kane, T.R., Fundamental kinematical relationships for single-track vehicles, International Journal of Mechanical Sciences, 1975, 17(8), 499–504.
[109] Kane, T.R., Steady Turning of Single-Track Vehicles, International Automotive Engineering Congress and Exposition, SAE International, Cobo Hall, Detroit.
[110] Man, G.K., Kane, T.R., Steady Turning of Two-Wheeled Vehicles, Automotive Engineering Congress and Exposition, SAE International, 715–735.
[111] Basu-Mandal, P., Studies on the dynamics and stability of bicycles, Ph.D. thesis, Indian Institute of Science, Bangalore, India, 2007.
[112] Basu-Mandal, P., Chatterjee, A., Papadopoulos, J., Hands-free circular motions of a benchmark bicycle, Proceedings of the Royal Society A: Mathematical, Physical and Engineering Sciences, 2007, 463(2084), 1983–2003.
[113] Kane, T.R., The Effect of Frame Flexibility on High Speed Weave of Motorcycles, Automotive Engineering Congress and Exposition, SAE International, 1389–1396.
[114] Roe, G.E., Theory of Castor Oscillations, Journal of Mechanical Engineering Science, 1973, 15(5), 379–381.
[115] Roe, G.E., Thorpe, T.E., Experimental Investigation of the Parameters Affecting the Castor Stability of Road Wheels, Journal of Mechanical Engineering Science, 1973, 15(5), 365–369.
[116] Roe, G.E., Thorpe, T.E., A Solution of the Low-Speed Wheel Flutter Instability in Motorcycles, Journal of Mechanical Engineering Science, 1976, 18(2), 57–65.
[117] Roe, G.E., Pickering, W.M., Zinober, A., The Oscillations of a Flexible Castor, and the Effect of Front Fork Flexibility on the Stability of Motorcycles, Automotive Engineering Congress and Exposition, SAE Transactions, 1397–1408.
[118] Sharp, R.S., A Review of Motorcycle Steering Behavior and Straight Line Stability Characteristics, Automotive Engineering Congress and Exposition, SAE International.
[119] Sharp, R.S., Alstead, C.J., The Influence of Structural Flexibilities on the Straight-running Stability of Motorcycles, Vehicle System Dynamics, 1980, 9(6), 327–357.
[120] Sharp, R.S., Jones, C.J., The Straight-running Stability of Single Track Vehicles, Vehicle System Dynamics, 1977, 6(2-3), 190–191.
[121] Verma, M.K., Scott, R.A., Segel, L., Effect of Frame Compliance on the Lateral Dynamics of Motorcycles, Vehicle System Dynamics, 1980, 9(4), 181–206.
[122] Splerings, P.T.J., The Effects of Lateral Front Fork Flexibility on the Vibrational Modes of Straight-Running Single-Track Vehicles, Vehicle System Dynamics, 1981, 10(1), 21–35.
[123] Giles, C., Sharp, R., Static and dynamic stiffness and deflection mode measurements on a motorcycle, with particular reference to steering behaviour, Road Vehicle Handling, I Mech E Conference Publications, C128/83, 185–192.
[124] Giles, C.G., Motorcycle steering behaviour, Ph.D. thesis, University of Leeds, Leeds, United Kingdom, 1985.
[125] Raines, M., Thorpe, T.E., The Relationship between Twist Axis and Effective Torsional Stiffness of a Motorcycle Frame, Proceedings of the Institution of Mechanical Engineers, Part D: Transport Engineering, 1986, 200(1), 69–73.
[126] Koenen, C., Pacejka, H.B., Vibrational modes of motorcycles in curves, Tech. rep., Motorcycle Safety Foundation, Nat. Highway Traffic Saf. Admin, Washington (DC), 1980, (Tech. Rep. HS-029 684).
[127] Koenen, C., Pacejka, H.B., The Influence of Frame Elasticity and Simple Rider Body Dynamics on Free Vibrations of Motorcycles in Curves, Vehicle System Dynamics, 1981, 10(2-3), 70–73.
[128] Koenen, C., The dynamic behaviour of a motorcycle when running straight ahead and when cornering, Ph.D. thesis, Delft University of Technology, Delft, Netherlands, 1983.
[129] Sharp, R.S., The Lateral Dynamics of Motorcycles and Bicycles, Vehicle System Dynamics, 1985, 14(4-6), 265–283.
[130] Nishimi, T., Aoki, A., Katayama, T., Analysis of Straight Running Stability of Motorcycles, 10th International Technical Conference on Experimental Safety Vehicles, SAE International, United States, 1080–1094.
[131] Katayama, T., Aoki, A., Nishimi, T., Control Behaviour of Motorcycle Riders, Vehicle System Dynamics, 1988, 17(4), 211–229.
[132] Pacejka, H., Sharp, R., Shear Force Development by Pneumatic Tyres in Steady State Conditions: A Review of Modelling Aspects, Vehicle System Dynamics, 1991, 20(3-4), 121–175.
[133] Bakker, E., Nyborg, L., Pacejka, H.B., Tyre Modelling for Use in Vehicle Dynamics Studies, SAE Technical Paper, SAE International, Detroit, Michigan.
[134] Bakker, E., Pacejka, H.B., Lidner, L., A New Tire Model with an Application in Vehicle Dynamics Studies, Autotechnologies Conference and Exposition, SAE International, United States, 83–95.
[135] Pacejka, H.B., Bakker, E., The Magic Formula tyre model, Vehicle System Dynamics, 1992, 21(sup001), 1–18.
[136] de Vries, E., Pacejka, H., Motorcycle tyre measurements and models, Vehicle System Dynamics, 1998, 29(sup1), 280–298.
[137] Sharp, R.S., Vibrational modes of motorcycles and their design parameter sensitivities, Vehicle NVH and Refinement, vol. 3, Mechanical Engineering Publications, 107–122.
[138] Sharp, R.S., The Application of Multi-Body Computer Codes to Road Vehicle Dynamics Modelling Problems, Proceedings of the Institution of Mechanical Engineers, Part D: Journal of Automobile Engineering, 1994, 208(1), 55–61.
[139] Gani, M., Sharp, R., Limebeer, D., Multi-body simulation software in the study of two-wheeled road vehicles, Proceedings of 35th IEEE Conference on Decision and Control, vol. 3, IEEE, 2804–2805.
[140] Gani, M., Limebeer, D., Sharp, R., Multi-Body Simulation Software in the Analysis of Motorcycle Dynamics, IFAC Proceedings Volumes, 1997, 30(8), 227–232.
[141] Gani, M.R., The computer assisted modelling, simulation and analysis of two-wheeled road vehicles, Ph.D. thesis, Imperial College London, London, United Kingdom, 1999.
[142] Sayers, M.W., Symbolic computer methods to automatically formulate vehicle simulation codes, Ph.D. thesis, University of Michigan, Michigan (USA), 1990.
[143] Sayers, M.W., Symbolic computer language for multibody systems, Journal of Guidance, Control, and Dynamics, 1991, 14(6), 1153–1163.
[144] Sayers, M., AUTOSIM, Vehicle System Dynamics, 1993, 22(sup1), 53–56.
[145] Imaizumi, H., Fujioka, T., Omae, M., Rider model by use of multibody dynamics analysis, JSAE Review, 1996, 17(1), 75–77.
[146] Imaizumi, H., Fujioka, T., Motorcycle-rider system dynamics by multibody dynamics analysis — Effects of the rear load on wobble motions and the control assembly, JSAE Review, 1997, 18(2), 201.
[147] Imaizumi, H., Fujioka, T., Motorcycle-rider system dynamics by multibody dynamics analysis: Effects of the rear load on wobble motions and the control assembly, JSAE Review, 1998, 19(1), 54–57.
[148] Cossalter, V., Doria, A., Lot, R., Steady Turning of Two-Wheeled Vehicles, Vehicle System Dynamics, 1999, 31(3), 157–181.
[149] Cossalter, V., Da Lio, M., Lot, R., Fabbri, L., A General Method for the Evaluation of Vehicle Manoeuvrability with Special Emphasis on Motorcycles, Vehicle System Dynamics, 1999, 31(2), 113–135.
[150] Sharp, R.S., Dynamics of Motorcycles: Stability and Control, Dynamical Analysis of Vehicle Systems, vol. 497 of CISM International Centre for Mechanical Sciences, Springer, Vienna, 2009, 183–230.
[151] Lot, R., A Motorcycle Tire Model for Dynamic Simulations: Theoretical and Experimental Aspects, Meccanica, 2004, 39(3), 207–220.
[152] Cossalter, V., Motorcycle dynamics, Race Dynamics, Milwaukee (USA), 2002.
[153] Tezuka, Y., Application of the magic formula tire model to motorcycle maneuverability analysis, JSAE Review, 2001, 22(3), 305–310.
[154] Pacejka, H., Tire and Vehicle Dynamics, Butterworth Heinemann, 2012.
[155] Cossalter, V., Doria, A., Lot, R., Ruffo, N., Salvador, M., Dynamic Properties of Motorcycle and Scooter Tires: Measurement and Comparison, Vehicle System Dynamics, 2003, 39(5), 329–352.
[156] Cossalter, V., Lot, R., Massaro, M., The influence of frame compliance and rider mobility on the scooter stability, Vehicle System Dynamics, 2007, 45(4), 313–326.
[157] Evangelou, S., Limebeer, D.J.N., Sharp, R.S., Smith, M.C., Control of motorcycle steering instabilities, IEEE Control Systems, 2006, 26(5), 78–88.
[158] Evangelou, S., Limebeer, D.J.N., Sharp, R.S., Smith, M.C., Mechanical Steering Compensators for High-Performance Motorcycles, Journal of Applied Mechanics, 2007, 74(2), 332–346.
[159] Le Henaff, Y., Dynamical stability of the bicycle, European Journal of Physics, 1987, 8(3), 207–210.
[160] Franke, G., Suhr, W., Riess, F., An advanced model of bicycle dynamics, European Journal of Physics, 1990, 11(2), 116–121.
[161] Good, McPhee, Dynamics of mountain bicycles with rear suspensions: modelling and simulation, Sports Engineering, 1999, 2(3), 129–143.
[162] Fajans, J., Steering in bicycles and motorcycles, American Journal of Physics, 2000, 68(7), 654–659.
[163] Getz, N., Control of balance for a nonlinear nonholonomic non-minimum phase model of a bicycle, Proceedings of 1994 American Control Conference - ACC ’94, vol. 1, IEEE, Baltimore, MD, USA, 148–151.
[164] Beznos, A., Formal’sky, A., Gurfinkel, E., Jicharev, D., Lensky, A., Savitsky, K., Tchesalin, L., Control of autonomous motion of two-wheel bicycle with gyroscopic stabilisation, Proceedings. 1998 IEEE International Conference on Robotics and Automation (Cat. No.98CH36146), vol. 3, IEEE, Leuven, Belgium, 2670–2675.
[165] Limebeer, D.J.N., Sharp, R.S., Bicycles, motorcycles, and models, IEEE Control Systems, 2006, 26(5), 34–61.
[166] Kooijman, J.D.G., Schwab, A.L., Meijaard, J.P., Experimental validation of a model of an uncontrolled bicycle, Multibody System Dynamics, 2008, 19(1-2), 115–132.
[167] Katayama, T., Nishimi, T., Energy Flow Method for the Study of Motorcycle Wobble Mode, Vehicle System Dynamics, 1990, 19(3), 151–175.
[168] Marumo, Y., Katayama, T., Analysis of Motorcycle Weave Mode by using Energy Flow Method, Journal of Mechanical Systems for Transportation and Logistics, 2009, 2(2), 157–169.
[169] Sharp, R.S., Optimal stabilization and path-following controls for a bicycle, Proceedings of the Institution of Mechanical Engineers, Part C: Journal of Mechanical Engineering Science, 2007, 221(4), 415–427.
[170] Moore, J., Hubbard, M., Parametric Study of Bicycle Stability (P207), The Engineering of Sport 7, Springer Paris, Paris, 2008, 311–318.
[171] Kooijman, J.D.G., Meijaard, J.P., Papadopoulos, J.M., Ruina, A., Schwab, A.L., A Bicycle Can Be Self-Stable Without Gyroscopic or Caster Effects, Science, 2011, 332(6027), 339–342.
[172] Moore, J.K., Kooijman, J.D.G., Schwab, A.L., Hubbard, M., Rider motion identification during normal bicycling by means of principal component analysis, Multibody System Dynamics, 2011, 25(2), 225–244.
[173] Schwab, A.L., Meijaard, J.P., Kooijman, J.D., Lateral dynamics of a bicycle with a passive rider model: stability and controllability, Vehicle System Dynamics, 2012, 50(8), 1209–1224.
[174] Lot, R., Massaro, M., Sartori, R., Advanced motorcycle virtual rider, Vehicle System Dynamics, 2008, 46(sup1), 215–224.
[175] Cossalter, V., Lot, R., Massaro, M., The chatter of racing motorcycles, Vehicle System Dynamics, 2008, 46(4), 339–353.
[176] Massaro, M., Lot, R., Cossalter, V., Brendelson, J., Sadauckas, J., Numerical and experimental investigation of passive rider effects on motorcycle weave, Vehicle System Dynamics, 2012, 50(sup1), 215–227.
[177] Evangelou, S., Limebeer, D.J.N., Tomas Rodriguez, M., Influence of Road Camber on Motorcycle Stability, Journal of Applied Mechanics, 2008, 75(6).
[178] Limebeer, D.J.N., Sharma, A., Burst Oscillations in the Accelerating Bicycle, Journal of Applied Mechanics, 2010, 77(6).
[179] Evangelou, S.A., Limebeer, D.J.N., Tomas-Rodriguez, M., Suppression of Burst Oscillations in Racing Motorcycles, Journal of Applied Mechanics, 2013, 80(1).
[180] Nakagawa, S., Samarasinghe, G., Haddaway, N.R., Westgate, M.J., O’Dea, R.E., Noble, D.W., Lagisz, M., Research Weaving: Visualizing the Future of Research Synthesis, Trends in Ecology & Evolution, 2019, 34(3), 224–238.
[181] Linnenluecke, M.K., Marrone, M., Singh, A.K., Conducting systematic literature reviews and bibliometric analyses, Australian Journal of Management, 2020, 45(2), 175–194.
[182] Tranfield, D., Denyer, D., Smart, P., Towards a Methodology for Developing Evidence-Informed Management Knowledge by Means of Systematic Review, British Journal of Management, 2003, 14(3), 207–222.
[183] Cook, D.J., Systematic Reviews: Synthesis of Best Evidence for Clinical Decisions, Annals of Internal Medicine, 1997, 126(5), 376.
[184] Xiao, Y., Watson, M., Guidance on Conducting a Systematic Literature Review, Journal of Planning Education and Research, 2019, 39(1), 93–112.
[185] Moher, D., Liberati, A., Tetzlaff, J., Altman, D.G., Preferred reporting items for systematic reviews and meta-analyses: The PRISMA statement, International Journal of Surgery, 2010, 8(5), 336–341.
[186] Aria, M., Cuccurullo, C., bibliometrix : An R-tool for comprehensive science mapping analysis, Journal of Informetrics, 2017, 11(4), 959–975.
[187] Corno, M., Giani, P., Tanelli, M., Savaresi, S.M., Human-in-the-Loop Bicycle Control via Active Heart Rate Regulation, IEEE Transactions on Control Systems Technology, 2015, 23(3), 1029–1040.
[188] Doria, A., Tognazzo, M., Cusimano, G., Bulsink, V., Cooke, A., Koopman, B., Identification of the mechanical properties of bicycle tyres for modelling of bicycle dynamics, Vehicle System Dynamics, 2013, 51(3), 405–420.
[189] Dabladji, M.E.h., Ichalal, D., Arioui, H., Mammar, S., Unknown-input observer design for motorcycle lateral dynamics: TS approach, Control Engineering Practice, 2016, 54, 12–26.
[190] Sequenzia, G., Oliveri, S.M., Fatuzzo, G., Calì, M., An advanced multibody model for evaluating rider’s influence on motorcycle dynamics, Proceedings of the Institution of Mechanical Engineers, Part K: Journal of Multi-body Dynamics, 2015, 229(2), 193–207.
[191] Wang, E.X., Zou, J., Xue, G., Liu, Y., Li, Y., Fan, Q., Development of Efficient Nonlinear Benchmark Bicycle Dynamics for Control Applications, IEEE Transactions on Intelligent Transportation Systems, 2015, 16(4), 2236–2246.
[192] Doria, A., Tognazzo, M., The influence of the dynamic response of the rider’s body on the open-loop stability of a bicycle, Proceedings of the Institution of Mechanical Engineers, Part C: Journal of Mechanical Engineering Science, 2014, 228(17), 3116–3132.
[193] Souh, B., Influence of tire side forces on bicycle self-stability, Journal of Mechanical Science and Technology, 2015, 29(8), 3131–3140.
[194] Doria, A., Favaron, V., Taraborrelli, L., Roa, S., Parametric analysis of the stability of a bicycle taking into account geometrical, mass and compliance properties, International Journal of Vehicle Design, 2017, 75(1/2/3/4), 91.
[195] Doria, A., Roa Melo, S.D., On the influence of tyre and structural properties on the stability of bicycles, Vehicle System Dynamics, 2018, 56(6), 947–966.
[196] Doria, A., Roa, S., Muñoz, L., Stability analysis of bicycles by means of analytical models with increasing complexity, Mechanical Sciences, 2019, 10(1), 229–241.
[197] Massaro, M., Cossalter, V., Cusimano, G., The effect of the inflation pressure on the tyre properties and the motorcycle stability, Proceedings of the Institution of Mechanical Engineers, Part D: Journal of Automobile Engineering, 2013, 227(10), 1480–1488.
[198] Cossalter, V., Doria, A., Giolo, E., Taraborrelli, L., Massaro, M., Identification of the characteristics of motorcycle and scooter tyres in the presence of large variations in inflation pressure, Vehicle System Dynamics, 2014, 52(10), 1333–1354.
[199] Doria, A., Taraborrelli, L., Out-of-plane vibrations and relaxation length of the tyres for single-track vehicles, Proceedings of the Institution of Mechanical Engineers, Part D: Journal of Automobile Engineering, 2016, 230(5), 609–622.
[200] Ballo, F., Gobbi, M., Mastinu, G., Previati, G., Motorcycle Tire Modeling for the Study of Tire–Rim Interaction, Journal of Mechanical Design, 2016, 138(5).
[201] Cossalter, V., Doria, A., Massaro, M., Taraborrelli, L., Experimental and numerical investigation on the motorcycle front frame flexibility and its effect on stability, Mechanical Systems and Signal Processing, 2015, 60-61, 452–471.
[202] Doria, A., Taraborrelli, L., The twist axis of frames with particular application to motorcycles, Proceedings of the Institution of Mechanical Engineers, Part C: Journal of Mechanical Engineering Science, 2016, 230(17), 3026–3039.
[203] Schröter, K., Pleß, R., Seiniger, P., Vehicle Dynamics Control Systems for Motorcycles, Handbook of Driver Assistance Systems, Springer International Publishing, Cham, 2016, 969–1006.
[204] Wu, Y.C., Chang, C.W., Development of 3-speed rear hub bicycle transmissions with gear-shifting mechanisms, Transactions of the Canadian Society for Mechanical Engineering, 2015, 39(3), 407–418.
[205] Corno, M., Panzani, G., Catenaro, E., Savaresi, S.M., Modeling and analysis of a bicycle equipped with in-wheel suspensions, Mechanical Systems and Signal Processing, 2021, 155, 107548.
[206] Maier, O., Györfi, B., Wrede, J., Kasper, R., Design and validation of a multi-body model of a front suspension bicycle and a passive rider for braking dynamics investigations, Multibody System Dynamics, 2018, 42(1), 19–45.
[207] de J. Lozoya-Santos, J., Cervantes-Muñoz, D., Tudón-Martínez, J.C., Ramírez-Mendoza, R.A., Off-Road Motorbike Performance Analysis Using a Rear Semiactive EH Suspension, Shock and Vibration, 2015, 2015, 1–13.
[208] Khadr, A., Houidi, A., Romdhane, L., Design and optimization of a semi-active suspension system for a two-wheeled vehicle using a full multibody model, Proceedings of the Institution of Mechanical Engineers, Part K: Journal of Multi-body Dynamics, 2017, 231(4), 630–646.
[209] Moreno-Ramírez, C., García-Fernández, P., De-Juan, A., Tomas-Rodríguez, M., Interconnected Suspension System on Sport Motorcycles, Mechanisms and Machine Science, vol. 17, 2014, 9–16.
[210] Moreno-Ramírez, C., Tomas-Rodriguez, M., Non linear optimization of a sport motorcycle’s suspension interconnection system, 2014 UKACC International Conference on Control (CONTROL), July, IEEE, 319–324.
[211] Moreno-Ramírez, C., Dynamic Analysis of Alternative Suspension Systems for Sport Motorcycles, Ph.D. thesis, City University London, London, United Kingdom, 2015.
[212] Moreno Ramírez, C., Tomás-Rodríguez, M., Evangelou, S.A., Dynamic analysis of double wishbone front suspension systems on sport motorcycles, Nonlinear Dynamics, 2018, 91(4), 2347–2368.
[213] Bonci, A., Longhi, S., Scala, G.A., Towards an All-Wheel Drive Motorcycle: Dynamic Modeling and Simulation, IEEE Access, 2020, 8, 112867–112882.
[214] Passas, P., Natsiavas, S., Paraskevopoulos, E., Numerical integration of multibody dynamic systems involving nonholonomic equality constraints, Nonlinear Dynamics, 2021, 105(2), 1191–1211.
[215] Boyer, F., Porez, M., Mauny, J., Reduced Dynamics of the Non-holonomic Whipple Bicycle, Journal of Nonlinear Science, 2018, 28(3), 943–983.
[216] Haddout, S., A practical application of the geometrical theory on fibered manifolds to an autonomous bicycle motion in mechanical system with nonholonomic constraints, Journal of Geometry and Physics, 2018, 123, 495–506.
[217] Limebeer, D.J.N., Massaro, M., Dynamics and Optimal Control of Road Vehicles, Oxford University Press, 2018.
[218] Zhang, Y., Zhao, G., Li, H., Multibody dynamic modeling and controlling for unmanned bicycle system, ISA Transactions, 2021.
[219] Escalona, J.L., Recuero, A.M., A bicycle model for education in multibody dynamics and real-time interactive simulation, Multibody System Dynamics, 2012, 27(3), 383–402.
[220] Escalona, J.L., Kłodowski, A., Muñoz, S., Validation of multibody modeling and simulation using an instrumented bicycle: from the computer to the road, Multibody System Dynamics, 2018, 43(4), 297–319.
[221] Turnwald, A., Liu, S., A Nonlinear Bike Model for Purposes of Controller and Observer Design, IFAC-PapersOnLine, 2018, 51(2), 391–396.
[222] Bloch, A., Nonholonomic Mechanics and Control, vol. 24 of Interdisciplinary Applied Mathematics, Springer New York, New York, USA, 2015.
[223] Xiong, J., Wang, N., Liu, C., Stability analysis for the Whipple bicycle dynamics, Multibody System Dynamics, 2020, 48(3), 311–335.
[224] Xiong, J., Wang, N., Liu, C., Bicycle dynamics and its circular solution on a revolution surface, Acta Mechanica Sinica, 2020, 36(1), 220–233.
[225] Tomiati, N., Magnani, G., Marcon, M., An experimental investigation of the bicycle motion during a hands-on shimmy, Vehicle System Dynamics, 2020, 1–17.
[226] Leonelli, L., Mancinelli, N., A multibody motorcycle model with rigid-ring tyres: formulation and validation, Vehicle System Dynamics, 2015, 53(6), 775–797.
[227] Ajmi, H., Aymen, K., Lotfi, R., Dynamic modeling and handling study of a two-wheeled vehicle on a curved track, Mechanics & Industry, 2017, 18(4), 409.
[228] Cossalter, V., Sadauckas, J., Elaboration and quantitative assessment of manoeuvrability for motorcycle lane change, Vehicle System Dynamics, 2006, 44(12), 903–920.
[229] Sorrentino, S., Leonelli, L., A study on the stability of a motorcycle wheel–swingarm suspension with chain transmission, Vehicle System Dynamics, 2017, 55(11), 1707–1730.
[230] Leonelli, L., Cattabriga, S., Sorrentino, S., Driveline instability of racing motorcycles in straight braking manoeuvre, Proceedings of the Institution of Mechanical Engineers, Part C: Journal of Mechanical Engineering Science, 2018, 232(17), 3045–3061.
[231] Cattabriga, S., De Felice, A., Sorrentino, S., Patter instability of racing motorcycles in straight braking manoeuvre, Vehicle System Dynamics, 2019, 1–23.
[232] Vallim, M.d.B., Dos Santos, J.M.C., Costa, A.L.A., Motorcycle Analytical Modeling Including Tire–Wheel Nonuniformities for Ride Comfort Analysis, Tire Science and Technology, 2017, 45(2), 101–120.
[233] Doria, A., Marconi, E., Munoz, L., Polanco, A., Suarez, D., An experimental-numerical method for the prediction of on-road comfort of city bicycles, Vehicle System Dynamics, 2020, 0(0), 1–21.
[234] Ferretti, G., Scaglioni, B., Rossi, A., Multibody Model of a Motorbike with a Flexible Swingarm, 10th International ModelicaConference, Lund, Sweden, 273–282.
[235] Arunachalam, M., Mondal, C., Singh, G., Karmakar, S., Motorcycle riding posture: A review, Measurement, 2019, 134, 390–399.
[236] Schwab, A., de Lange, P., Happee, R., Moore, J.K., Rider control identification in bicycling using lateral force perturbation tests, Proceedings of the Institution of Mechanical Engineers, Part K: Journal of Multi-body Dynamics, 2013, 227(4), 390–406.
[237] Wang, P., Yi, J., Liu, T., Stability and Control of a Rider–Bicycle System: Analysis and Experiments, IEEE Transactions on Automation Science and Engineering, 2020, 17(1), 348–360.
[238] Dialynas, G., de Haan, J.W., Schouten, A.C., Happee, R., Schwab, A.L., The dynamic response of the bicycle rider’s body to vertical, fore-and-aft and lateral perturbations, Proceedings of the Institution of Mechanical Engineers, Part D: Journal of Automobile Engineering, 2020, 234(7), 1944–1957.
[239] Doria, A., Tognazzo, M., Cossalter, V., The response of the rider’s body to roll oscillations of two wheeled vehicles; experimental tests and biomechanical models, Proceedings of the Institution of Mechanical Engineers, Part D: Journal of Automobile Engineering, 2013, 277(4), 561–576.
[240] Shafiekhani, A., Mahjoob, M., Akraminia, M., Design and implementation of an adaptive critic-based neuro-fuzzy controller on an unmanned bicycle, Mechatronics, 2015, 28, 115–123.
[241] Baquero-Suárez, M., Cortés-Romero, J., Arcos-Legarda, J., Coral-Enriquez, H., Correction to: A robust two-stage active disturbance rejection control for the stabilization of a riderless bicycle, Multibody System Dynamics, 2019, 46(1), 107–107.
[242] Leonelli, L., Limebeer, D.J.N., Optimal control of a road racing motorcycle on a three-dimensional closed track, Vehicle System Dynamics, 2020, 58(8), 1285–1309.
[243] Kim, Y., Kim, H., Lee, J., Stable control of the bicycle robot on a curved path by using a reaction wheel, Journal of Mechanical Science and Technology, 2015, 29(5), 2219–2226.
[244] Park, S.h., Yi, S.y., Active Balancing Control for Unmanned Bicycle Using Scissored-pair Control Moment Gyroscope, International Journal of Control, Automation and Systems, 2020, 18(1), 217–224.
[245] Tofigh, M., Mahjoob, M., Hanachi, M., Ayati, M., Fractional sliding mode control for an autonomous two-wheeled vehicle equipped with an innovative gyroscopic actuator, Robotics and Autonomous Systems, 2021, 140, 103756.
[246] Zhang, Y., Song, K., Yi, J., Huang, P., Duan, Z., Zhao, Q., Absolute Attitude Estimation of Rigid Body on Moving Platform Using Only Two Gyroscopes and Relative Measurements, IEEE/ASME Transactions on Mechatronics, 2018, 23(3), 1350–1361.
[247] Romualdi, L., Mancinelli, N., De, F., Sorrentino, S., A new application of the Extended Kalman Filter to the estimation of roll angles of a motorcycle with Inertial Measurement Unit, FME Transactions, 2020, 48(2), 255–265.
[248] Vasquez, F., Lot, R., Rustighi, E., Pegoraro, R., Tyre forces estimation for off-road motorcycles, Mechanical Systems and Signal Processing, 2021, 150, 107228.
[249] Hung, N.B., Lim, O., A review of history, development, design and research of electric bicycles, Applied Energy, 2020, 260(December 2019), 114323.
[250] Ba Hung, N., Jaewon, S., Lim, O., A study of the effects of input parameters on the dynamics and required power of an electric bicycle, Applied Energy, 2017, 204, 1347–1362.
[251] Marinov, M., Valchev, V., Stoyanov, R., Andreev, P., An Approach to the Electrical Sizing of The Electric Motorcycle Drive, 2018 20th International Symposium on Electrical Apparatus and Technologies (SIELA), IEEE, Bourgas, Bulgaria, 1–4.
[252] Hieu, L.t., Khoa, N.X., Lim, O., An Investigation on the Effects of Input Parameters on the Dynamic and Electric Consumption of Electric Motorcycles, Sustainability, 2021, 13(13), 7285.
[253] Drummond, E., Condro, P., Cotton, B., Cox, C., Pinegar, A., Vickery, K., Prins, R., Design and Construction of an Electric Motorcycle, 2019 Systems and Information Engineering Design Symposium (SIEDS), IEEE, 1–6.
[254] Matsuda, Y., Murase, T., Kawai, D., The Feasibility Study of a Design Concept of Electric Motorcycle, SAE Technical Papers, vol. 2015-Septe.
[255] LeBel, F.A., Pelletier, L., Messier, P., Trovao, J.P., Battery Pack Sizing Method - Case Study of an Electric Motorcycle, 2018 IEEE Vehicle Power and Propulsion Conference (VPPC), IEEE, 1–6.
[256] Caliwag, A.C., Lim, W., Hybrid VARMA and LSTM Method for Lithium-ion Battery State-of-Charge and Output Voltage Forecasting in Electric Motorcycle Applications, IEEE Access, 2019, 7, 59680–59689.
[257] Abu Hanifah, R., Toha, S.F., Mohamad Hanif, N.H.H., Kamisan, N.A., Electric Motorcycle Modeling for Speed Tracking and Range Travelled Estimation, IEEE Access, 2019, 7, 26821–26829.
[258] Farzaneh, A., Farjah, E., Analysis of Road Curvature’s Effects on Electric Motorcycle Energy Consumption, Energy, 2018, 151, 160–166.
[259] Farzaneh, A., Farjah, E., A Novel Smart Energy Management System in Pure Electric Motorcycle Using COA, IEEE Transactions on Intelligent Vehicles, 2019, 4(4), 600–608.
[260] Yao, D., Fan, G., Zhang, C., Jiang, J., Wu, F., Design and Simulation of An Energy Management Algorithm for Extended-Range Electric Bicycles, Proceedings of the 2015 International Conference on Electrical, Automation and Mechanical Engineering, vol. 13, 211–214.
[261] Guanetti, J., Formentin, S., Corno, M., Savaresi, S.M., Optimal energy management in series hybrid electric bicycles, Automatica, 2017, 81, 96–106.
[262] Alcazar, M., Perez, J., Mata, J., Cabrera, J., Castillo, J., Motorcycle final drive geometry optimization on uneven roads, Mechanism and Machine Theory, 2020, 144, 103647.